eee.7-2.1 telecommunication systems
TRANSCRIPT
EEE.7-2.1 Telecommunication Systems
Couse contents: * Introduction to signals and telecommunication systems. * Analog to
digital conversion. * Digital transmission through a channel with added white Gaussian
noise. * Digital transmission through AWGN channel of limited bandwidth. *
Multiplexing and multiple access.
EEE.7-2.2 Microwaves
Couse contents: Basic principles of high frequency transmission lines. * Smith charts.
* Matching calculations.* Microwave transmission through metallic waveguides. * TE
and TM wave guiding in orthogonal waveguides. * Analysis of microwave cavities.
EEE.7-2.3 Digital Signal Processing
Couse contents: * Introduction to DSP. * Codecs (A/D and D/A conversion).
*Elementary DSP functions and properties. * Discrete Fourier Transform and its fast
implementations. * Introduction to digital Filter design. * Hardware implementations.
EEE.7-2.4 Electroacoustics I
Course contents: * Sound applications. * Electroacoustic systems. * Sound wave
description. * Wave equation. * Equivalent circuits of mechanical and acoustical
systems. * Subsystems of acoustic facilities. * Sound measurements.
Elective Courses (2/5)
EEE.7-2.5 Advanced Topics in Networking and Security
This course is on advanced topics in Networking and Security. Upon successful
completion of the course the student will have specialized knowledge over Computer
Networks and Interconnected Electronic Systems over the Internet. Based on that, the
student will be able to: * Understand how routing protocols and related algorithms
work, and to know and deploy various routing techniques over IP networks. * Know
and distinguish the various network architectures, their characteristics as well as the
way network devices and remote access protocols operate. * Have an in-depth
knowledge of the interconnection technologies used in IP networks (VLAN, MPLS,
PPoE, PPoA) as well as the characteristics of the physical media. * Design and
implement IP based networks, taking into account the parameters that have an impact
on the design of each topology and use scenario. * Understand the security issues that
apply, on a case-by-case basis as well as to know the techniques used to enhance the
security of systems in networked and cyber physical systems. * Cooperate in a team to
provide integrated solutions for the secure interconnection of networked electronic
devices and systems. * To work in complex work environments with emphasis on data
security and privacy. Keywords: Computer networks, Routing Protocols,
Interconnection Technologies, Network Design and Creation, Network and System
Security.
EEE.7-2.6 Web Applications Development
Course contents: * Web Applications Development, *Addressing security and privacy
issues.: * Different data types that can be generated and exchanged (i.e. Open Data,
Interconnected, etc.) in web applications. * Databases (Relational, Non-Relational) that
can be used to store web related data. * Modern CMS for web development. *
Programmable interfaces (APIs) for data transfer. * Visualizations of stored web data.
* Data security and privacy.
EEE.7-2.7 Photonics Technology
Course contents: * Properties of light and optics principles. * Telecommunication
applications and devices. * Special photonic technologies, devices and applications. *
Light source characterization. * Power measurements. * Fiber optics. * Power spectrum
measurements. *Optical modulation techniques.
EEE.7-2.8 Measurement Systems and Sensors
Course contents: Circuits and noise interference isolation techniques in sensor
measurements. * Digital circuits for reading sensor measurements. * Function and
characteristics of sensor matching circuits. * Basic sensor categories for non electrical
physical properties. * Graphic programming for virtual instrumentation, * High
frequency measurements.
EEE.8-2.1 Optical Communications
Course contents: * Basic optics principles. * Optical waveguides. * Optical fiber
properties. * Transmission through optical fibers. * Modulation techniques. * Optical
amplifiers. * Optical network topologies. * Free space optical communications.
EEE.8-2.2 Antennas
Course contents: *Antenna theory. * Antenna radiation and power transport. * Antenna
characteristics and related equivalent circuits. * Linear antennas. * Idol theory and loop
antennas. * Antenna types. * Printed antennas.
EEE.8-2.3 Internet of Things
Course contents: * Introduction to IoT. * Sensors and Microcontrollers. * Data
communication protocols. * Wireless sensor networks. * Environments, platforms and
application development tools. * Personal network technologies. * Wearable devices.
* Security issues. * Blockchain algorithm.
Elective Courses (3/7)
EEE.8-2.4 Digital Audio and Speech Technologies
Course contents: * Introduction to audio and speech processing techniques. * Speech
digital processing. * Applications and systems for speech processing. * Coding and
compression of sound data.
EEE.8-2.5 Image Processing and Pattern Recognition
Course contents: * Digital Image postulates: Chromatometry, Popular image formats.
Image representation into popular software packages. * Relations between pixels. Basic
image processing techniques. * Image enhancement: Histogram oriented methods and
filtering. * Image enhancement: Frequency Domain representation and filtering. * Edge
detection techniques. Compression postulates. The JPEG standard. * Machine learning
principles and pattern recognition postulates. Introduction to probabilities, Linear
Algebra, SVD. * Bayesian theory. Parametric and non-parametric methods. Linear
discriminant functions. · The curse of dimensionality. Clustering: Machine learning
tools: PCA, LDA
EEE.8-2.6 Microwave Devices
Course contents: * Multi-passive microwave elements and description of the operation
through the Z, Y, ABCD and scattering matrices. * Principle of operation of the
rectangular directional coupler, matrix scattering, applications, broadband directional
couplers. Directional microstrip couplers. * Microwave cavity wavemeter with
coupling opening in waveguide, attenuator operating principle and load implementation
techniques waveguide adjustment, phase shifter. * Techniques for design and operation
of microwave antennas - horn antennas, slot antennas, parabolic reflectors. * Ferrites
and ferrite devices and properties at high frequencies: Isolation principle of operation,
three-port microwave element circulator - applications. * Magic Tee, type H and type
E splitters - applications. * Active microwave components - microwave sources -
characteristics and requirements for microwave applications. Beam interaction
electrons with electromagnetic wave. * The Klystron tube, as a source of microwave
frequency generation - Klystron with reflector - structure and oscillation rates - power
- frequency - reflector voltage. Multi-cavity Klystron as an amplifier. * Gunn diode -
GaAs energy bands and negative resistance effect - construction of Gunn diode -
maximum output power - equivalent circuit. * TWT traveling wave tube as a broadband
amplifier. * The Magnetron tube - internal cavity structure - electron motion - field
distribution. * Impact diode, varactor diode, PIN diode. * Noise in microwave lamps.
Parametric Amplifier.
EEE.8-2.7 Wideband Communications
Course contents: * Modern modulation technologies. * Spread spectrum
communication systems. * Multi-antenna communication systems.
Ok- EEE.8-2.8 Electroacoustics II
Course contents: * Human auditory system characteristics. * Closed space acoustics. *
Acoustical parameters of electroacoustic function facilities. * Noise effect on humans.
* Design of electroacoustic and sound systems.
EEE.8-2.9 RF Design
Course contents: * Introduction. Electromagnetic spectrum, radio frequency (RF)
frequencies, basic system architectures and RF transceivers. Media, reflections,
maximum power transfer. * Lumped and distributed circuits. The electromagnetic
resistance of the resistor, capacitor and inductor at high frequencies (RF). Resonance.
Quality factor. Impedance Transformation. Smith Chart. * High frequency transistor
models. Equivalent RF circuits, parameters S. Integrated circuits RF, MIC, MMIC. *
Filter design. Filter categories. Passive and active filters. Design for a specific filter
class. Microstrip filters.* Small signal amplifiers. Low noise amplifiers. Antenna noise
temperature and circuit noise factor. Cascade topology noise figure. Tuned amplifiers
and Stagger amplifiers.* Power amplifiers. Operating classes, 1 dB compression point,
harmonic and intermodulation products. * Mixers and DAC/ADC. Gilbert cell, up and
down frequency conversion, amplitude modulation. Mixers features. Sampling
theorem. Analog-to-digital and digital-to-analog converters. * Oscillators. Oscillators
using lumped elements. Negative feedback, Barkhausen criterion. Wien bridge
oscillators, phase shift oscillators, crystal oscillators. Design oscillators using a Smith
chart. Phased Locked Loop (PLL). Frequency synthesizers.* Two-way and multi-port
networks. Resistance and conductivity matrices, ABCD, hybrid, and scattering
matrices. * Measurement of scattering parameters. Microwave models and RF
components for CAD software.* RF systems. Analysis and synthesis of RF systems
using scattering parameters. Design using simulation software.
EEE.9-2.1 Information Theory and Coding
Course Contents: * Introduction. * Measures of Information. * Source and Channel
Modelling. * Source Coding. *Channel Capacity. * Channel Coding.
EEE.9-2.2 Wireless Propagation
Course contents: * Introduction to the Course - Overview of Basic Concepts. Planar
Wave - Polarization - Antenna fundamentals. * Fundamental Propagation Mechanisms.
Free Space propagation, Reflection, Refraction / Transmission from flat surfaces. *
Fundamental Propagation Mechanisms: Reflection - Multilayer Transmission
structures, Scattering from rough surfaces. * Fundamental Propagation Mechanisms.
Diffraction from slots, edges, angles. * Shading Phenomena and Losses. * Multipath
Propagation and Narrowband Channels Fading). * Wideband Fading. * Smooth
Atmospheric Refraction and line of sight (LOS) Criteria. * Attenuation from Rain and
Atmospheric Gases. * Propagation Phenomena and Fixed line of sight links design
Principles. * Propagation Phenomena and Design Principles of Cellular coverage for
mobile Communications. * Propagation Phenomena and Wireless Communications-
Networks Transmission and Receiving Technologies.
Elective Courses (4/9)
EEE.9-2.3 Electromagnetic Compatibility
Course contents: * Introduction to EC and definitions. Prototypes and regulations. *
Tests in EC. * Open space control field. Silent chamber. Reverberation chamber. TEM
cells. * Design features and specifications of sound chambers. * Shielding
effectiveness. Absorption losses. Reflection losses. Corrections for multiple reflections.
* Reduction of shielding efficiency through openings and slots - cavity resonance. *
Capacitive conductor coupling. * Inductive conductor coupling. * Twisted pair cables.
Coaxial cables. * Conductive interferences. Electrostatic discharge. Electrical
transitions. Lightning currents. Operation of protection circuits. * Grounding of
systems and devices. Grounding categories. AC supplies and grounding safety. * Signal
grounding. Grounding loops. Strangulation coils.
EEE.9-2.4 Cloud Computing
Course contents: * Introduction. Service models. Development models. * Virtualization
techniques and hypervisors. * Technologies and platforms. * Software defined
networks and network function virtualization. * Use of information storage
(containers). * Best practices for high availability cloud computing infrastructures. *
Real cloud computing infrastructures. * IT automation mechanisms. * Use of Docker
toolset.
EEE.9-2.5 Mobile Communication Networks
Course contents: * Introduction. Definitions and function of mobile communication
network architecture. Mobile communication protocols. * Design of mobile
communication networks. * Wireless channel modeling. Narrow/Wide band mobile
communications. * Digital modulation techniques. Coding for search and correction of
errors. Spread spectrum technologies. OFDM. MIMO. * Multiple access of wireless
channel techniques. * Architecture and topologies of mobile networks. GSM. GPDS.
3G WCDMA. * Introduction to 5G mobile communications networks.
EEE.9-2.6 Wireless Data Networks
Course contents: * Introduction to wireless data. * Reference architectures for wireless
data networks. Components of a wireless LAN. WLANs: the physical layer. Medium
access control. * Mobility and internet protocols. * Data communications in cellular
networks. * Security in wireless data networks. * Routing in wireless LANs. * Wireless
personal area networks and ultrawide band communications. * Broadband wireless
access.
EEE.9-2.7 Digital Audio and Video Broadcasting
Course contents: * Introduction. History of radio/television. Definitions of related
physical quantities. EM spectrum. AM/FM modulation. AM/FM receivers. Antennas.
EM wave propagation. AM/FM radio emitter and receiver. Stereo emission. Production
and transmission of television signal. Scanning. Synchronization. Quality. *
Digitization and compression of audio and video signals. DCT, JPEG. MPEG1.
MPEG2. MPEG4. * Information processing, cryptography, coding, modulation.
MPEG1 System Layer. MPEG2 Transport / Program. FEC/Formating: Energy
Dispersal, Outer/Inner Coding. QPSK/QAM, OFDM. Guard Interval. * Digital
terrestrial and satellite emission and reception. Low Noise Block Converters (LNBs).
DVB-T, DVB-S, DVB-S2. * New technologies and applications.
EEE.9-2.8 Radar and Remote Sensing
Course contents: * Introduction. * Radar function. * Antennas for radar and target
angle. Phased arrays. Rotation and stabilization systems. Target angle measurement. *
Radar equation and target radio cross-section. Backscattering coefficient and target
trace. Target size measurement.* Scattering from simple targets. Scattering from
infinite cylinder, sphere, and conductive plate. * Scattering from multiple targets. SW1-
SW5 type targets. SNR for complex targets. Simulation of scattering signals. *
Detection theory and radar signal. Probability for single pulse target detection. *
Specialized radar systems. Frequency modulation radar. Concurrent phase radar. Early
warning radar. Surveillance radar. * Radar receivers. Matched filter receiver. Radar
pulse uncertainty function. * Passive sensors. Black and gray body radiation * Image
synthesis radar. Linear antennas. SAR type radars. * New technologies and
applications. Time-space radar signal processing. MIMO radar. Microwave radar.
EEE.9-2.9 Satellite Communications
Course contents: * Parameters of satellite orbits, determination of azimuth and
elevation angles of the satellite from a terrestrial station.* Link budgets for the up- and
down-links and calculation of the carrier to noise ratio (C / N) at the ground terminal
receiver. * Calculation of signal to noise ratio (SNR) or rate error (BER) for a satellite
link. * Design a satellite communication system to achieve specific targets for the signal
to noise ratio (S / N) and BER using appropriate multi-access techniques - improvement
of BER through ARQ and FEC coding techniques. * Effect of rain attenuation on a
satellite link and availability of the link based on the geographical location of the
terrestrial terminals. * Types and dimensions of antennas used in satellites and ground
stations. * GEO or LEO satellite systems for voice, video or data using analogue or
digital configuration. * International regulatory framework for satellite services and
space applications.
EEE.9-2.10 Telecommunication Systems Design
Course contents: * Introduction and basic digital model of a telecommunication system
(Digital Radio). Software defined radio. Digital signal processing. * Classical design
and implementation of telecommunication systems. Representation of signals.
Modulation. SDR emitter/receiver. * Hardware and software tools for digital
implementation of telecommunication subsystems. FPGA-based SDR development
boards) ETTUS and ADALM-PLUTO. Applications in Matlab/Python/C++. *
Application examples for modulation and demodulation (AM, DSBsc, SSB) and 2D
(M-PSK, M-QAM). OFDM. * Design and implementation of specialized
telecommunication systems. Channel modeling, coding, synchronization, control etc.
EEE.7-3.1 Microcontrollers-Embedded Systems
Course contents: * General purpose systems – Embedded systems. * Software-
hardware co-design. * Embedded system characteristics. * Applications of embedded
systems. * Basic components of embedded systems. * Cyber-physical system
applications of embedded systems. * Limitations of embedded systems. * Design and
function parameters.
EEE.7-3.2 Automatic Control Systems II
Course contents: * Applied automated control systems. * Compensation via phase lead
/ phase lag networks. * Representation in state space –State space equations solving. *
Equivalent descriptions in state space. * Controllability – Observability. * Lyapunov
stability analysis. * Design in state space, * Optimal control. * Non-linear systems
analysis.
EEE.7-3.3 Digital Signal Processing
Couse contents: * Introduction to DSP. * Codecs (A/D and D/A conversion).
*Elementary DSP functions and properties. * Discrete Fourier Transform and its fast
implementations. * Introduction to digital Filter design. * Hardware implementations.
Elective Courses (3/6)
7-3.4 Semiconductor Devices
Course contents: * Solid state and semiconductor physics elements. Electron as a wave.
Electron structure of elements. * Crystal structure. Semiconductor models. * Atomic
density. Mobile carriers in metals and semiconductors. * Semiconductor impurities.
Fermi level. * Ohmic contacts. * Carrier scattering. * Current in semiconductors. *
Semiconductor devices. Diode. BJT. MOSFET.
EEE.7-3.5 Mixed Analogue – Digital Circuits
Course contents: * Positive and Negative feedback electronic circuits. Oscillation
criterion. Classes of Oscillators. * RC oscillators (Wien oscillator, Phase shift
oscillator, Double T oscillator, etc). LC Oscillators (Colpitts oscillator, Hartley
oscillator, Clapp oscillator, etc). Crystal oscillator circuits. Voltage Controlled
Oscillators. Phase locked Loops. * Introduction to multivibrators. Astable, Monostable,
Bistable multivibrators. OpAmp implementation of multivabrators. * Introduction to
Signal Conditioning. IC 555 and application. Clock circuits. Non-linear dynamic
systems, chaotic circuits. A/D and D/A circuits. Circuit Analog/Digital interaction. *
Introduction to passive electronic filters. Transfer Function, Bode analysis. 1st, 2nd and
higher order filters. Analysis and design of low-pass, high-pass, and band pass filters.
* Introduction to active electronic filters. Sallen-Key filters. 1st, 2nd and higher order
filters. Analysis and design of low-pass, high-pass and band-pass filters.
EEE.7-3.6 Measurement Systems and Sensors
Course contents: * Introduction to sensors. Definitions. Applications. MEMS.
Microsensors. * Measurement system characteristics. Sensors, transducers, converters.
* Sensor characteristics. * Noise sources and interferences in measurement systems and
sensors. Capacitive and inductive coupling. Differential amplifiers. Isolators. * Analog
electronic measurement systems. * Digital electronic measurement systems. * ADCs.
* Non-electrical quantity measurements and related sensors. * Temperature
measurement sensors. * Strain gauges. * Position sensors. * Hall-effect sensors. *
Humidity sensors. * Piezoelectric sensors. * Flow sensors. * Chemical sensors. * Bio-
sensors.
EEE.7-3.7 Integrated Circuits Design (VLSI)
Course contents: * Introduction to VLSI design and the various integrated circuit
architectures. * Methodologies and tools uses in IC design. * Layout design and CMOS
IC fabrication processes. * Analysis of basic and more complex CMOS circuits. * Static
and Dynamic RAM design. * Sequential logic, flip-flop and register design with VLSI
techniques.
EEE.7-3.8 Web Applications Development
Course contents: * Data varieties, storage and representation. JSON. XML *
Applications of relational and non-relational data bases. SQL. CRUD. PHP. * Content
management systems. Wordpress. Joomla. Drupal. * Internet services. SOAP. REST.
Javascript. * Security and privacy applications. SSL. Authentication. Authorization.
Accounting.
EEE.8-3.1 Operating Systems
Course contents: Introduction to OS. * Processes. * Threads. * Memory management.
* File systems and their management. * Windows OS. Linux OS and programming. *
Android OS. * Specialized OS.
EEE.8-3.2 Computational Intelligence
Course contents: Introduction to artificial and computational intelligence. *
Introduction to machine learning. * Artificial neuron model. * Perceptron. * Multilayer
perceptron neural networks. * RBF neural networks. * Other neural network
architectures. * Hardware implementation of neural networks. * Introduction to fuzzy
logic. * Fuzzy logic systems. * Genetic algorithms. * Swarm intelligence. *
EEE.8-3.3 Databases
Course contents: * Introduction to databases and non-relational databases for big-data
applications. * Comparison and differences of RDBMS and non RDBMS. * Servers
for databases. * Tools, applications and technologies related to databases.
EEE.8-3.4 Robotics
Course contents: * Introduction to Robotics. * Robotic Architecture. * Kinetic Analysis
of Robotic Systems. * Static Analysis of Robotic Systems. * Dynamic Analysis of
Robotic Systems. * Robot Programming.
EEE.8-3.5 Embedded Systems Programming
Course contents: High level embedded systems development with ASIC or FPGA. *
MSP430 microcontrollers. * MBED platform. * Simuling platform. * Microcontroller
programming applications.
EEE.8-3.6 Nanoelectronic Devices
Course contents: * Introduction to quantum mechanics. Photoelectric effect. Hydrogen
spectrum. De Broglie equation. Discrete spectrums. Electrochemical potential in
metals. * Energy levels in low dimensionality systems. Quantum wells. Molecular
bonds. Tunneling. Energy levels in solids. * Bottom up approach study in
nanoelectronic systems. Molecular electronics. I-V and G-V characteristics. * Carrier
movement in nano MOS transistors. Ballistic conductivity. Carbon nanotude
transistors. Nano-wires. * Memory devices with nanoparticles. Hot electrons and
carrier transport models through thin insulators. * C-V characteristics in MOS and
nano-memories. * Coulomb blockage. Quantum points. Bandgap widening. Optical
properties. Single electron transistors. Coulomb diamonds. * Metallic nanoparticles.
Single molecule sensors. Photovoltaic elements. * Electronic, optical properties and
transport phenomena in nanodevices. * Characterization of nanodevices. * Introduction
to quantum computing.
EEE.8-3.7 Internet of Things
Course contents: * Introduction to IoT. * Sensors and Microcontrollers. * Data
communication protocols. * Wireless sensor networks. * Environments, platforms and
application development tools. * Personal network technologies. * Wearable devices.
* Security issues. * Blockchain algorithm.
EEE.8-3.8 Image Processing and Pattern Recognition
Course contents: * Digital Image postulates: Chromatometry, Popular image formats.
Image representation into popular software packages. * Relations between pixels. Basic
image processing techniques. * Image enhancement: Histogram oriented methods and
filtering. * Image enhancement: Frequency Domain representation and filtering. * Edge
detection techniques. Compression postulates. The JPEG standard. * Machine learning
principles and pattern recognition postulates. Introduction to probabilities, Linear
Algebra, SVD. * Bayesian theory. Parametric and non-parametric methods. Linear
discriminant functions. · The curse of dimensionality. Clustering: Machine learning
tools: PCA, LDA
EEE.9-3.1 Modern Microcomputer Systems
Course contents: * Development platforms and tools. Arduino. Beagleboard. Raspberry
Pi. NXP Freedom. TI Sensortag. C.H.I.P. PocketCHIP. * Introduction to embedded
cyber physical systems (CPS). State-flow implementation. Specification Description
Language (SDL). * Microcontroller programming with MBED. * Raspberry Pi
development platform. * Connection, control and communication of Raspberry Pi.
EEE.9-3.2 Intelligent Control
Course contents: * Fuzzy control. * Dynamic models and neurodynamics. * Inverse
neural control. * Control parameter calibration using metaheuristic search methods. *
Predictive model control for linear systems. Dynamic matrix control. * Predictive
model control for non-linear systems. * Adaptive control models. * Adaptive control
techniques.
EEE.9-3.3 Quantum Electronic Devices
Course contents: * Spontaneous and forced emission. Einstein equations. * Function of
lasers. Pumping. Three and four level systems. * Laser spectrum. Widening
mechanisms. Longitudinal models. Spectrum comb. * Optical cavities. Design and
stability criteria. * Pulse lase technologies. Q-switching. Mode-locking. * Transport of
fast pulses through matter. * Maxwell equations for non-linear materials. * 2nd order
non-linear processes. * Conditions for energy and momentum conservation. * Ideal
phase matching methods. * Partial phase matching methods.
EEE.9-3.4 Industrial Engineering
Course contents: * Introduction to Industrial Engineering. * Classic Industrial
Automation. * Programmable Logic Controllers (PLCs). * Supervisory Control and
Data Acquisition (SCADA). * Computer Numerical Control (CΝC). * Computer
Integrated Manufacturing (CIM). * Introduction to Techno-Economic Theory. *
Manufacturing organization. * Standardization and Control of Quality and Reliability.
EEE.9-3.5 Digital Control Systems
Course contents: * Discrete time control. * Z-transform and inverse Z-transform. *
Impulse invariance system discretization. Zero-order hold system discretization.
Bilinear transform. Pade approximation. * Discrete time system description. Observer
canonical form. Controller canonical form. * Closed control discrete time system
analysis in state space. Controllability. Observability. Unit cycle criterion. Jury
criterion. Nyquist criterion. Bode criterion. * Design of digital controllers. Dead-beat
control. Lueberger observers. State feedback. Design of PID. Computer adjustments
and calibration.
EEE.9-3.6 Mechatronics
Course contents: * Introduction to mechatronics. * Dynamics of moving systems. *
Movement control. * Electromechanical actuators. * Analog electronics in mechatronic
systems. * System design. The V model. * Energy transducers/actuators. *
Programming/Control of mechatronic systems. * Sensors. * Electronic circuits for
sensor/transducer signal processing. * Applications of mechatronic systems.
EEE.9-3.7 Cloud Computing
Course contents: * Introduction. Service models. Development models. * Virtualization
techniques and hypervisors. * Technologies and platforms. * Software defined
networks and network function virtualization. * Use of information storage
(containers). * Best practices for high availability cloud computing infrastructures. *
Real cloud computing infrastructures. * IT automation mechanisms. * Use of Docker
toolset.
EEE.9-3.8 Biomedical Technology
Course contents: * Current technologies, sectors and applications of biomedical
technology. * Modalities used in biomedical technology, * Theory of 1D biomedical
modalities (EEG, ECG etc.). * Theory of 2D and 3D biomedical modalities
(tomography, imaging methods). * Comparisons of biomedical imaging systems. *
Effects of using, and maintaining biomedical systems on humans. * E-Health and m-
Health applications. * Bio-signal processing. * Digital biomedical image processing.
Image alignment. * Medical decisions and diagnosis assistance using biomedical
systems.